Coupling between Photochromism and Second-Harmonic Generation

16320

J. Phys. Chem. 1995, 99, 16320-16326

Coupling between Photochromism and Second-Harmonic Generation in Spiropyran- and Spirooxazine-Doped Polymer Films Yomen Atassi, Jacques A. Delaire,* and Keitaro Nakatani Laboratoire de Photophysique et de Photochimie Supramolkculaires et Macromolkculaires (P. P.S.M., U.R.A. 1906 of C.N.R.S.), Ecole Normale Suptrieure de Cachan, 61 avenue du PrCsident Wilson, 94235 Cachan Ckdex, France Received: Februav 16, 1995; In Final Form: June 9, 1995@

The photochemical ring opening of spiropyrans in polymethylmethacrylate (PMMA) host films in the presence of a high-voltage electric field (2-5 MV/cm) leads to a photo-orientation of photomerocyanines. Since photomerocyanines have rather high first-order hyperpolarizabilities, this photo-orientation leads to secondharmonic generation (SHG). The second-order susceptibility & of PMMA films doped with 6-nitro- 1’,3’,3’trimethylspiro[2H-l-benzopyran-2,2’-indoline] (25% w/w) has been measured at 10 p m N . If a PMMA film doped with spiropyran and preoriented by corona poling at 90 “C is irradiated in the UV, an SHG signal of photomerocyanine is also observed as a result of a memory effect of the orientation of spiropyran molecules. The photoswitching of this nonlinear optical property can be inverted by visible light irradiation. Only partially reversible switching is observed because of a gradual light-induced disorientation of photomerocyanine dipoles. Photochemical quantum yields of the spiropyran photomerocyanine reaction have also been determined in PMMA for one system. Dipole moments and hyperpolarizabilities of closed and open forms have been calculated by semiempirical and finite field methods for an analogous system.

*

Introduction

0

‘L

One of the main advantages of organic polymers in the manufacture of organic devices for integrated optics is their flexibility in accommodating very different chromophores (either in guest-host matrices or in covalently linked copolymers) so that their properties can be tuned very precisely.’-3 Another advantage, which is of great interest to us, is the possibility of combining two different properties in the same matrix. In this respect, photorefractive polymers provide a good example, as they combine photoconducting and second-order nonlinear optical (NLO)properties4 We present herein a new class of materials exhibiting two distinct properties: photochromism and second-order NLO properties. We have already demonstrated new features created by the combination of these two properties on one such system based on Disperse Red One dye4,5(DRI or N-ethyl-N-(hydroxyethyl)((4-nitrophenyl)azo)aniline), a pushpull azobenzene derivative. In polymers doped with this molecule or in poly(methylmethacry1ate-co-DR1) copolymer films, a photoassisted poling takes place at room temperature if the film is irradiated under an applied electric field of a few megavolts per ent ti meter;^-^ this is due to the thermally reversible trans-cis photoisomerization, which leads to a preferential orientation of the molecules along the applied electric field. The system studied in this work is based on the well-known photochromic couples spiropyrdphotomerocyanine and spirooxazinelphotomerocyanine dissolved in polymer matrices (mainly polymethylmethacrylate, PMMA). The photochromism of these compounds has been studied for many years”-” and is still being thoroughly investigated because of their potential applications in photochromic glasses or lenses, in optical memories and optical switching applications. The photochromic reaction is depicted in Figure 1. Recently, experimental values of dipole moments and firstorder hyperpolarizabilities p were reported for stable merocyanines with an indoline heterocycle as a donor and different %Abstract published in Adcunte 4 C S Ahstructc October 1, 1995

@ R R

7v2,lenanli form

Heierocyile le 8

indolint Senzoth~aroline~

Subrutuemc

Figure 1. Photochromic reaction between spiropyran, spirooxazine. and photomerocyanine.

acceptor groups. For 1,3-diethylthiobarbituricacid as acceptor, the authors found a negative p value (8 = -46 x esu) and a dipole moment of 7.4 x lo-’* esu.I5 This negative value has been attributed to the zwitterionic ground state of the merocyanine. It has already been pointed out previously for classic merocyanine dyes.I6 In addition, second-harmonic generation (SHG) of poled films (thermally assisted poling) of liquid-crystal polymers doped with photomerocyanines has already been The main objective of this work is to demonstrate how one can combine photochromism and second-order NLO effects in such systems. This combination leads to two distinct phenomena: the first is a photoassisted poling (PAP) of the photomerocyanines in polymer films in the presence of an external electric field at room temperature, which is similar to the orientation of DR1 in PMMA that we already observed; the second is the “photoswitching” of the NLO properties of a polymer film doped with spiropyran and previously poled under an external electric field. A preliminary report on PAP has been given in the case of one specific s p i r ~ p y r a n ; the ’ ~ work is extended herein to different spiropyrans as well as to some spirooxazines whose structures are similar to those of spiropyrans but whose photochemical stability is reputed to be better.

0022-365419512099-16320$09.00/0 0 1995 American Chemical Society

Spiropyran- and Spirooxazine-Doped Polymer Films

J. Phys. Chem., Vol. 99, No. 44,1995 16321 Probe laser NdlYAG 1064 nm Polarization in the incidence plane (p-polarization)

R2

3rd harmonics NdlYAG 355 nm

1 SP.L -RI- = -S-, -R2 = -CHI, -Rj = -0CH3, 8-methoxy-3-methyl-6-nitro-3'methylspiro[2H- 1-benzopyran-2,2'-benzothiazoline] %L -RI- = -S-, -Rz = -0CzH5, -R3 = -OCHj; 3-ethoxy-8-methoxy-6-nitro-3'methylspiro[2H- l-benzopyran-2.2'-benzothiazoline] sei. -RI- = -C(CH3)2-. -Rz = -H, -R3 = -H; 6-nitro-l',3',3'-trimethylspiro[2HI -benzopyran-2,2-indoline] && -RI- = -C(CHh-, -Rz = -H, -R3 = -CH2SC2H5; 8-(ethylthio)methyl-6nitro- 1',3',3'-trimethylspiro[2Hl-benzopyran-2,2'-indoline]

-Rl = -H, -R2 = -H, -R3 = - ptperidinyl, ' -R4 = -H; 1,3,3-trimethyl-6'piperidinylspiro[indoline-2,3'-[3H]naphtoxazine] or "Red PNO" SEA-RI = H, -R2 = -H, -R3 = -H, -R4 = -H; 1,3,3-trimethylspiro[indoline. 2,3'-[3Hlnaphtoxazine] or "Blue A" SEZ-RI = sCH3, -Rz = -CH3, -Rj = -H, -R4 = -H; 1,3,3,4,5pentamethylspiro[indoline-2,3'-[3H]naphtoxazine] or "Blue D" sE& -RI = -CI, -Rz = -H, -R3 = -H. -R4 = -H; 5-chloro-1,3,3trimethylspiro[indoline-2,3'[3H]-naphthoxazine] -R1=-H, -R2= -H, -R3-R4- E -CH=CH-CH=CH-; 1,3,3trimethylspiro[indoline-2,3'-[3H]-phen~~oxazine]

Figure 2. Spiropyran and spirooxazine molecules used in this study.

Experimental Section

1. Polymer Films. Doped polymer films of spiropyrans and spirooxazines (SP1 to SP9, Figure 2) in PMMA were prepared by spin coating on an I T 0 (indium tin oxide) glass plate from a chloroform solution containing PMMA (6% w/w) and chromophore (10% or 25% w/w relative to PMMA). The films (thickness of around 1 pm) were dried at 110 "C for 2 mn and at 80 "C for 2 h. SP3, SP8, and SP9 were purchased from Aldrich Co.; SP5, SP6, and SP7 were provided by EniChem Co.; and SP1, SP2, and SP4 were provided by Professor Guglielmetti (Universit6 d'Aix-Marseille 11). The PMMA used was Elvacite 2041 from DuPont, and the chloroform was purchased from Prolabo (spectrophotometric grade). All chemicals were used without further purification. 2. Poling Process. Two types of poling were performed depending on the aim of each experiment. (i) Classical corona poling at high temperatures (thermally assisted poling): Under a voltage of 5 kV applied to a gold-plated stainless steel needle located 1 cm from the surface of the film, the polymer film was heated up to 90 "C (near Tg,the glass transition temperature of PMMA) and slowly cooled down to room temperature. (ii) PAP at room temperature: Since SHG measurements were performed in situ during poling, this process will be described in detail in paragraph 4 of this experimental section. 3. Kinetical Measurements. Photochemical reaction quantum yields, as well as thermal back reaction rate constants, were measured on a continuous pump-probe irradiation with one beam perpendicular to the other and both having an incidence angle of 45" . The pump beam was generated by a Xe-Hg arc lamp (450 W), and the probe beam by a Xe arc lamp (150 W). In order to select the appropriate wavelength, interference filters were put on the pump path and monochromators on the probe path. The photon flux of the pump beam was measured by using Aberchrome 540, an actinometer

Circular Polarization

5 kV

Corona Needle.

'A\

Polymer film

Fundamental and second harmonic beams

IT0 on glass substrate

Figure 3. Experimental setup for in situ measurements of SHG (configuration around the sample).

purchased from Aberchromics Ltd. The intensity of the probe beam was negligible compared to that of the pump beam. 4. Second-Harmonic Generation (SHG). SHG measurements were carried out using as the probe beam the fundamental (1064 nm) of a Q-switched, mode-locked picosecond Nd-YAG laser (30 ps pulse width, 10 Hz repetition rate). The polymer film sample was mounted on a rotating plate. For all experiments described in this paper, the incidence angle was set at 30°,and polarization was fixed in the incidence plane (so-called p-polarization). For each laser pulse, the SHG signal arising from the sample was integrated and compared to the SHG signal arising from a urea powder reference, in order to eliminate laser fluctuation. The integrated signal was monitored by a Keithley 199 multimeter connected to a PC compatible computer. Absolute values of the quadratic susceptibility d33 were determined by comparison with the second-harmonic signal generated by a reference quartz crystal (dil = 0.5 pmN). The sample's environment, described in Figure 3, allowed us to pump and/or pole the molecules, while probing the sample with the fundamental beam, and to follow PAP. Pumping was performed with the third harmonics of the same laser (355 nm) with a beam flux of approximately 10 mW/cm2. The polarization was made circular by means of a ;1/4 plate, and the incidence was normal to the sample's surface. Poling at room temperature could also be performed on this setup. A high voltage of 5 kV was applied on the corona needle located at around 1 cm off the film surface. I T 0 served as ground electrode. A few of the poling experiments mentioned in this paper were performed by contact poling. For this purpose, a thin layer of gold was deposited on films prepared in conformance with the process described in paragraph 1 of this experimental section. This technique enables avoiding the use of the corona needle, and the actual voltage across the film can be measured by a casual multimeter. Results 1. Calculation of Molecular First-Order Hyperpolarizability by a Finite Field Method. Calculation of the molecular firstorder hyperpolarizability of the studied molecules has been performed by the finite field technique in combination with the MNDO molecular orbital method.21 The MNDO Hartree-Fock matrix elements were computed using the MOPAC molecular orbital program. It is generally admitted that the polarizability of a molecule with respect to an electric field is described by the creation of an induced dipole moment. One can use a power series expansion of the dipole moment to describe its interaction with the electric field as follows: ,Mi(@

= /A:

f

&pj j

f

D i j g j E k f ZyjjkiEjEg, f j.k

...

(1)

j.kJ

where pp is the permanent dipole moment, aijthe elements of the polarizability tensor, and P j j k and y i j k , the elements of the

16322 J. Phys. Chem., Vol. 99, No. 44, 1995

Atassi et al.

0.4

Figure 4. Calculated u and vectorial p for compound PM1

4

a,

0.2

00

first and second hyperpolarizability tensors, respectively. The first-order hyperpolarizability is given as the second derivative of the dipole moment with respect to the applied field. In the finite field method, this derivative is calculated by fitting the dipole moment into a polynomial of the applied field E. According to the Hellman-Feynman theorem,?’

0

20

I0

30 x103 Time /s

40

50

Figure 5. Kinetical study of the thermal back reaction for the SP3PM3 system followed at 584 nm. Since only PM3 absorbs at this wavelength, OD is directly proportional to the concentration of PM3. The kinetics were fitted to a biexponential. TABLE 1: Rate Constants for the Thermal Back Reaction

compound SP3 SP5 SP6 SP7 SP9

In practice, this is numerically performed by computing

The values of the electric field components used in our calculations were equal to 0.001 au. Finally, we give, as usual, the projection of vectorial /?on the ground state dipole moment, which was defined as follows: (4) +

+

+

where p.6 = p y ~ . Tpipu,. pju: and pi = plil + p i j j + plik. Structural data of SP1 and PM1 are not available. However, we managed to provide a potential structure of these compounds based on crystallographic data of analogous molecule^.^^.?^ The most stable conformation of PM1 was deduced from published results (Figure 4).’4,.’5 Values of p are 1.9 x and -43.0 x lo-”’ esu for SPl and PM1, respectively. The dipole moment increases from 7.5 D for SP1 to 13.6 D for PM1. In PM1, both vectors make an angle of 142”. These calculations confirm the expected increase of the absolute value of /3, in going from the closed to the open form of the molecule. Negative p values for photomerocyanines have Already been found theoretically and experimentally (by electric-field-induced second-harmonic generation) for stable merocyanine~.’~.’~ This negative sign was recently interpreted as a consequence of the zwitterionic characteristic of merocyanine’s ground state (Figure l), which leads to an electronic polarization opposite to the charge transfer in the ground state. The presence of the nitro group on the benzene ring of compounds SP1 to SP4 enhances the electron-attracting power and yields its high absolute ,i3 value relative to that of the related photomerocyanine. Detailed calculations will be provided elsewhere.26 2. Kinetics Measurements. Rate Constants of the Thermal Back Reaction. After the photostationary equilibrium was reached by irradiating a spiropyran film at 320 nm, the back reaction was allowed to proceed in the dark at room temperature. Optical density (OD) measurements at the absorption maximum of the photomerocyanine (A,,,, see Table 1) were carried out over a few hours (Figure 5). The kinetics is quite well fitted to a biexponential function (Table 1). The rate constants obtained compare well with those already reported in the They are generally lower than in nonpolar solvents and have about the same order of magnitude s-’ in as in polar solvents: 2.5 s-’ in toluene and 7.7 x

kl1s-l

4 M X

584 625 580 562 589

7

k2Is-l

x 10-4

1 x 10-4

1 x 10-2

6 x lo-“ 4 x 10-3 2 x 10-3

4 x lo-’ 2 x 10-2 2 x 10-2

1 x lo-‘

TABLE 2: Experimental Data Concerning the Photochemical Reaction with Pump Beams at 320 and 372 nm

wavelengtNnm mol-’ cm-’ cp~31Lmol-’ cm-l pump wavelengthinm beam fluxleinstein s-’ dm-? cSp!/L

320

372

11.7 x 10’ 6.6 x 10’ 11.7 x lo3 10.3 x 10’

al%

320 6.8 x lo-* 84

QSP-PM

0.102

588 0

13.2 x 10’

372 2.1 x lo-’

17 0.135

0.019 0.023 ethanol for compound SPl ,31.32 The biexponential behavior is usually attributed to the presence of different conformations of photomerocyanine. However, it can also be due to the presence of different locations in the polymeric matrix, though this phenomenon is usually better described by a stretched exponential. Quantum Yields. Although irradiation in the UV region is usually utilized for the ring-opening reaction, both spiropyran and photomerocyanine absorb in this region, and photochemical reaction may occur both ways. The quantum yields ( P s p - p ~ and (PPJI-SP were determined for SP3PM3 in the UV region, as this system provides the most efficient conditions for this experiment: first, it has a very good colorability, enabling us to conduct accurate measurements of OD change, and, second, its thermal back reaction is the slowest among the available compounds, thereby allowing us to neglect this process. Since we cannot measure c p ~ the , extinction coefficient of PM3, directly, we have to combine two methods described in the literature for quantum yield determination: Fischer’s method3’ determines the extinction coefficient of PM3 at the desired wavelength, and Rau’s method34 ultimately enables us to reach (PSP-PJI and @ p ~ - - ~ p . Fischer’s method needs to use pump-probe experiments at different wavelengths mentioned in the results given in Table 2. From this method, we get the EPM values at the three wavelengths utilized in the experiments. From these data, we deduce a, the reaction extent at two pump wavelengths, and then @SP-P.M and (Pp>(-sp. The colorability (product of ( P s p - p ~ and c p ~ ) ,which describes the ability of this spiropyran to evolve color, is 2.4 x IO3 at 588 nm when E is expressed in L mol-’ cm-’. The values obtained are rather high for photoisomerization processes in polymer matrices and are close to those reported QPM-SP

J. Phys. Chem., Vol. 99, No. 44, 1995 16323

Spiropyran- and Spirooxazine-Doped Polymer Films in the l i t e r a t ~ r e . ~ ' In , ~ ~these determinations, all side reactions have been neglected. In particular, due to the slow rate constants given in Table 1 and to the short time scale of steady-state irradiation for all these measurements (a few minutes), it is justified to neglect the thermal back reaction. 3. Photoassisted Poling of Photomerocyanines Demonstrated by SHG. PMMA films of thicknesses of approximately 1 p m doped with spiropyrans or spirooxazines (10% w/w) were studied with the experimental setup described above for SHG measurement at an incidence of 30" with in situ W irradiation and electric field poling (Figure 3). As expected, depending on the p values calculated above, spiropyrans are not good candidates for SHG. However, the photomerocyanines display a much better efficiency. Furthermore, their high dipole moment (in the ground state) may lead to orientation under an applied external electric field. Two kinds of experiments have been conducted, in accordance with the sequence of external perturbations applied to the samples: either the electric field and the UV irradiation are both acting at the same time (experiment I) or the UV irradiation is being performed first and then the electric field is being switched on (experiment 11). In both experiments, the times involved are the same. A third kind of experiment will be described in the next section. In the case where polarization of the fundamental laser beam is within the incidence plane, the intensity of the second-harmonic signal, I2,, is36

1

Electric field

1

uv

12

08 \

-w

04

O

W

.

.

'

I

'

'

1

600

400

0

2oo T i m I s

I Electric field uv

I

Figure 6. Photoassisted poling at room temperature monitored in situ on the SP3 (spiropyran)-PM3 system (in PMMA, 25% w/w): comparison between experiment I (simultaneous poling and pumping) and experiment I1 (poling after pumping). Note the higher SHG intensity reached in experiment I for the same pumping and poling field conditions. Contact poling was chosen for better control of the poling field.

J

uv

I

06 04

where 1, is the coherence length of the polymer at frequency w , I, the intensity of the fundamental beam, 1 the film thickness, and an effective second-order susceptibility, which is a The susceptibility tensor linear combination of and components can be written as (indices in uppercase refer to the bulk coordinates, and those in lowercase, to the individual molecules) I

&:

02

I F.......... , . . . . . . . .i . . . . . . . . . .

x:.

xj:2-2@;w,@) = N f x 2 @ ) f , ( w l f K ( w ) C O ~ j , ( - 2 @ ; 0 , ( ( , > ) , ~ ~

(6)

in which N is the density number of NLO chromophores, fi,A, a n d f ~are the local field factors, and the term in brackets is a weighted sum of the values of the different &'s, an average over all orientations of the dipolar chromophore in the polymer. According to the low value of p for spiropyran, we may only consider the contribution of photomerocyanine molecules. So, 12w is proportional to N2 ( N being the density number of photomerocyanine molecules) and to the square of p, averaged over all the orientations of the molecules. In Figure 6, the 12w signal for compound SP3 is plotted versus time during the two different experiments described above. In these experiments, contact poling was performed with an applied voltage of 200 V between the gold coating and the ITO. The same film was used in two different spots for both experiments. The main feature is the large increase of the SHG signal, which starts in experiment I when UV light is switched on and in experiment I1 when the electric field is switched on (with the ring opening reaction having been carried out before). The plateau value reached in experiment I was 10 p m N after a few minutes of irradiation. The second feature is the difference between the maximum intensities reached in both experiments; i.e., the maximum intensity reached in experiment I is approximately twice the amount in experiment 11. This enhancement factor has been obtained on many samples oriented either by contact poling or by corona poling. The latter method yields higher potential37 but is sensitive to UV and visible light illumination and charge injection phenomena.8 Although the

.......,

i

0.6

a0

u.4 0.2

0 0

300

600

900

1200

Time I s

Figure 7. Photoassisted poling at room temperature monitored in situ on the SP3-PM3 system (in PMMA, 10% w/w) and OD followed at 532 nm. Since only PM3 absorbs at this wavelength, OD 1s directly proportional to the concentration of PM3.

exact ratio fluctuated between 1.5 and 3, it was always larger than 1. Since irradiation conditions were exactly the same in both experiments, the number of photomerocyanine molecules formed during both experiments was the same, and the difference in intensity was only due to a difference in the efficiency of orientation (see Discussion). The kinetics of both signals' growth are also different (Figure 6). The increase of 120 in experiment I1 is characteristic of the dynamics of rotational diffusion of dipoles under an applied electric field in polymer media.38 It is highly nonexponential, with a fast increase followed by a much slower one. The increase of 12w in experiment I has been compared in Figure 7 with the rate of ring opening as probed by the measurement of the increase of OD at 532 nm (second harmonics of the NdYAG laser being used as a probe) in the absorption band of the photomerocyanine molecule. In experiment 11, we considered the influence of the time delay between the end of the W irradiation and the beginning of corona poling: when this delay was increased from 10 to 100 s, we observed that the longer the delay, the lower the plateau value we obtained for 4